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Evaluation of Radar Performance Degradation due to Standoff Jamming (Unclassified)
: PERSONA. AuThOR(S)
Chi, Yoon Kyu
3j Tt?t OF REPORT
Master's Thesis3 ''ME COHERED30V r O
4 DATE OF REPORT {.Ynr Month 0*f)
1992 SeptemberS PAGE COuNT
74
6 Sl-pplE ventary no'aton The views expressed in this thesis are those of the author and do
not reflect the official policy or position of the Department of Defense or U.S. Govt.
COSAT COOES
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18 So8,ECT 'ESMS Continue on revert* if necemry *mj •aent.fy by £>'0<« number)
Standoff Jamming, Radar Evaluation
) ^.aS'RAL' 'Continue on rtvtrt* it neteiury tnd identify by blOKk number)
This thesis evaluates the performance degradation of Airport Surveillance
Radar(ASR-9) due to standoff jamming. ASR-9 data was taken from open literature on
this civilian radar. Jammer parameters which are representative of the actual system
were postulated to keep the study unclassified. Using these parameters the effect of
standoff jamming on detection of targets is evaluated. This evaluation is performed by
finding the change in radar SNR due to jamming and computing the probability of detection
with and without jamming.
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Approved for public release; distribution is unlimited.
Evaluation of Radar Performance Degradation -
Due to Standoff Jamming
by
£hi, Yoon kyu
Lieutenant Colonel, Korea Air Force
B.S., Korean Air Force Academy, 1980
Submitted in partial fulfillment
of the requirements for the degree of
MASTER OF SCIENCE IN SYSTEMS ENGINEERING
(ELECTRONIC WARFARE)
from the
NAVAL POSTGRADUATE SCHOOLSeptember 1992
ABSTRACT
This thesis evaluates the performance degradation of Airport Surveillance
Radar(ASR-9) due to standoff jamming. ASR-9 data was taken from open literature on
this civilian radar. Jammer parameters which are representative of the actual system
were postulated to keep the study unclassified. Using these parameters the effect of
standoff jamming on detection of targets is evaluated. This evaluation is performed by
finding the change in radar SNR due to jamming and computing the probability of
detection with and without jamming.
/AJi
TABLE OF CONTENTS
I. INTRODUCTION 1
A. BACKGROUND 1
B. OBJECTIVE 2
C. RELATED WORK 3
D. OVERVIEW 3
II. RADAR DESCRIPTION 4
A. SURVEILLANCE RADAR 4
B. THE AIRPORT SURVEILLANCE RADAR(ASR-9) 5
1. Moving Target Detector(MTD) 6
a. Signal Processing 9
b. Correlation and Interpolation 13
c. Scan-to-Scan Correlation and Tracking 13
2. Weather Channel 13
III. THE DEPLOYMENT OF STANDOFF JAMMING AND JAMMING
EQUATIONS 15
A. STANDOFF JAMMING TACTICS AND DEPLOYMENT 15
B. L IING EQUATIONS 16
1. Mainbeam Jamming 16
a. Radar Range Reduction 16
b. Burn-through Range 20
2. Sidelobe Jamming 22
a. Radar Range Reduction 22
b. Burn-through Range 23
IV. THE EVALUATION OF ASR-9 RADAR PERFORMANCE 25
A. ASR-9 RADAR AND JAMMER PARAMETERS 25
1. ASR-9 Radar Parameters 25
2. Jammer Parameters 27
B. MATHEMATICAL EVALUATION . . 27
1. Radar Performance Evaluation without Jamming 27
2. Radar Performance Evaluation with Mainbeam Jamming ... 30
a. Maximum Detection Range with Barrage Jamming ... 30
b. Maximum Detection Range with Spot Jamming 33
c. Burn-through Range and Crossover Range 36
3. Radar Performance Evaluation with Sidelobe Jamming .... 38
a. Maximum Detection Range with Barrage Jamming ... 38
b. Maximum Detection Range with Spot Jamming 41
c. Burn-through Range and Crossover Range 43
V. ECCM FEATURES 46
A. ECCM FOR MAINBEAM JAMMING 47
B. ECCM FOR SIDELOBE JAMMING 49
1. Low Sidelobe Antennas 50
2. Sidelobe Blanker 50
3. Sidelobe Canceler 51
VI. CONCLUSION AND RECOMMENDATION 53
APPENDIX. A COMPUTER PROGRAM 55
1. MATLAB PROGRAM FOR THE PROBABILITY OF DETECTION
WITH/WITHOUT STANDOFF JAMMING 55
2. MATLAB PROGRAM FOR BURN-THROUGH RANGE 56
APPENDIX. B PROBABILITY OF DETECTION VS TARGET RANGE . 57
1. JAMMER ERP : 10 dBW (JAMMING RANGE : 50 NM) 57
2. JAMMER ERP : 20 dBW (JAMMING RANGE : 50 NM) 58
3. JAMMER ERP : 30 dBW (JAMMING RANGE : 50 NM) 59
4. JAMMING RANGE : 25 NM (JAMMER ERP : 20 dBW) 60
5. JAMMING RANGE : 100 NM (JAMMER ERP : 20 dBW) 61
LIST OF REFERENCES 62
INITIAL DISTRIBUTION LIST 63
VI
LIST OF FIGURES
FIGURE 2.1 MTD BLOCK DIAGRAM 7
FIGURE 2.2 MTD RESOLUTION CELL 10
FIGURE 2.3 THE FREQUENCY RESPONSE OF THE THREE PULSE
CANCELER AND THE EIGHT PULSE DOPPLER FILTER
BANK 11
FIGURE 2.4 THE MATRIX OF RANGE RESOLUTION CELL AND FILTER
NUMBER AT CFAR 11
FIGURE 2.5 BLOCK DIAGRAM OF THE ASR-9 WEATHER
PROCESSOR 14
FIGURE 4.1 THE PROBABILITY OF DETECTION VS TARGET RANGE
FOR ASR-9 WITHOUT JAMMING 29
FIGURE 4.2 NORMALIZED RADAR DETECTION RANGE VS STANDOFF
JAMMER RANGE FOR THE MAINBEAM BARRAGE
JAMMING 31
FIGURE 4.3 THE PROBABILITY OF DETECTION VS TARGET RANGE
FOR ASR-9 WITH MAINBEAM BARRAGE JAMMING . . 32
FIGURE 4.4 NORMALIZED RADAR DETECTION RANGE VS
STANDOFF JAMMER RANGE FOR THE MAINBEAM
SPOT JAMMING 34
vn
FIGURE 4.5 THE PROBABILITY OF DETECTION VS TARGET RANGE
FOR ASR-9 WITH MAINBEAM SPOT JAMMING 35
FIGURE 4.6 NORMALIZED RADAR DETECTION RANGE VS STANDOFF
JAMMER RANGE FOR THE SIDELOBE BARRAGE
JAMMING 39
FIGURE 4.7 THE PROBABILITY OF DETECTION VS TARGET RANGE
FOR ASR-9 WITH SIDELOBE BARRAGE JAMMING ... 40
FIGURE 4.8 NORMALIZED RADAR DETECTION RANGE VS STANDOFF
JAMMER RANGE FOR THE SIDELOBE SPOT JAMMING 42
FIGURE 4.9 THE PROBABILITY DETECTION VS TARGET RANGE FOR
ASR-9 WITH SIDELOBE SPOT JAMMING 43
FIGURE 4.10 BURN THROUGH RANGE OF MAINBEAM JAMMER AND
SIDELOBE JAMMER 45
FIGURE 5.1 SIDELOBE BLANKER BLOCK DIAGRAM 51
FIGURE 5.2 A SIMPLIFIED BLOCK DIAGRAM OF SIDELOBE
CANCELER 52
FIGURE 6.1 THE PROBABILITY OF DETECTION VS TARGET RANGE
FOR ASR-9 WITH MAINBEAM AND SIDELOBE
JAMMING 54
Vlll
ACKNOWLEDGMENT
I am cordially thankful to God and I wish to express my appreciation to the
Korean Air Force for providing the valuable opportunity to study. I would like to
personally express my gratitude to my thesis advisor, Professor G.S. Gill, for his
patient guidance, dedicated lengthy counsel and continuous support during the
preparation of this thesis. Without his help, my effort would never have been
successful. I am also very grateful to Professor David C. Jenn, who carefully read and
corrected my script.
Finally, I thank to my wife, Jong Ok and daughter, Yong Ju, whose sacrifice
and patience have been most supportive during my study at NPGS.
I. INTRODUCTION
A. BACKGROUND
The basic purpose of jamming is to introduce signals into an enemy's electronic
system which degrade its performance so that it is unable to perform its intended
mission. There are two fundamental categories of jamming: noise jamming and
deceptive jamming. In this thesis only noise jamming will be considered. Noise
jamming has the effect of obscuring the radar target by immersing it in noise. Noise
can be introduced into the victim radar either through the mainlobe or through the
sidelobes.
Surveillance radars are vulnerable to jamming in the mainbeam because the
jamming gets the large gain of the antenna's mainbeam. When this occurs, the
narrow sector in the direction of the jammer will appear as a radial strobe on the
PPI display. The direction to the jammer can be determined, but its range and the
ranges of any targets are masked by the noise and thus remain unknown. Jamming
of the radar through the sidelobes is much more difficult to accomplish because of
large jammer effective radiated power(ERP) required to compensate for the low
antenna sidelobes. However if sidelobe jamming is successful it denies the radar
surveillance in all directions as the entire display can be obliterated. Even the
direction of targets and jammer is denied. To avoid such disastrous consequences
radar ECCM features such as sidelobe blanking, sidelobe canceling and low antenna
sidelobes are employed to mitigate the effects of the sidelobe jamming.
Radar - ECM is a high stake duel in the modern military warfare in which
jammer tries to render the hostile radar useless. Radar in turn needs to operate with
minimal effect on performance under jammer attacks.
The subject of radar performance degradation in presence ofjamming is of high
interest to both radar and jamming communities. There are two approaches to the
subject of radar performance evaluation in the presence ofjamming. In one approach
the jamming threat is estimated by intelligence and the radar performance is
computed for the defined threat. In the second approach no jamming threat is
assumed, instead the following question is addressed: " What type and amount of
jamming will prevent the radar from performing its mission and is such a jammer
feasible to build ?" In this thesis, the first approach is taken.
B. OBJECTIVE
The objective of this thesis is to evaluate the effect of jamming on surveillance
radar performance. To keep the study unclassified, a representative jamming threat
was postulated without using actual data from an existing jammer. The same
approach has been taken in the selection of radar parameters. Airport surveillance
radar(ASR-9) is of no military significance. Therefore the parameters of this radar
are used in the studv.
C. RELATED WORK
The maximum detection range of ASR-9 can be computed using the radar
equation described by Skolnik[Ref.l], and ASR-9 Radar parameters are taken from
Schleher[Ref.4 p:406]. Representative jammer parameters have been assumed.
D. OVERVIEW
This thesis consists of six chapters. Chapter I gives an introduction. Chapter II
describes the performance of ASR-9 radar. Chapter III contains standoff jamming
tactics and the jamming equations for mainbeam and sidelobe jamming. Chapter IV
describes the radar and jammer parameters, and evaluates the radar performance
with no jamming, with the mainbeam jamming and with the sidelobe jamming.
Chapter V provides the ECCM for mainbeam and sidelobe jamming. Finally, chapter
VI summarizes the radar performance degradation due to jamming.
II. RADAR DESCRIPTION
A. SURVEILLANCE RADAR
A surveillance radar is used to maintain cognizance of traffic within a selected
area, such as an airport terminal area or air route. A search radar is one which is
used primarily for the detection of targets in a particular volume of interest. The
difference in definition means that the surveillance radar provides for the
maintenance of track files on the selected traffic, while the search radar output may
be simply a warning or one time designation of a target for acquisition by a
tracker[Ref.6 p:315]. When target track files are maintained by a surveillance radar,
the overall radar is usually called a track-while-scan (TWS) radar. This TWS radar
develops the target vectors which determine the absolute motion characteristics of
the target. The motion characteristics of the target can be used to ascertain the
relative threat posed by the target and to predict the future position of the target.
Usually, surveillance radars must provide three-dimensional(3-D)information
for air search, and two-dimensional(2-D)information for surface search. The 2-D
radar has been the standard even for air search for many years and is still utilized
for civilian air traffic control applications. Military applications for surveillance radar
are generally being replaced by the newer 3-D radar types. The move towards 3-D
radars in military applications is driven by the need to provide height data in high
traffic-density situations. A primary function of both 2-D and 3-D surveillance radars
is the estimation of target ground track velocity vectors. The track data is used in
military systems for threat identification,threat evaluation, weapon assignment,
predicting target position and kill evaluation. In civilian air traffic control systems it
is used for traffic control, conflict alert and approach control. The requirements for
military systems are more stringent than for civilian systems due to the higher
accelerations found in military systems, while in civilian systems the accelerations
are lower due to path regularity and pilot collaboration associated with civilian air
traffic control operation[Ref.4 pp:265-266]. Most the civilian air traffic control radars
are of the 2-D type and ASR-9 is a 2-D radar.
B. THE ASR-9
The S-band ASR-9 is a modern airport surveillance radar designed by
Westinghouse for the FAA (Federal Aviation Administration). This radar is installed
at more than 100 major airports in the Continental United States and Hawaii. The
ASR-9 makes use of the very latest state of the art electronics technology. It
operates at S band(2.7-2.9 GHz) with a pulse width of 1.05 ^s, a 1.3 degree azimuth
beamwidth, an antenna rotation rate of 12.5 rpm, a PRF of the order of 1200 Hz,
and a peak transmitter power of 1200 kW. This radar provides the information for
aircraft targets within a 60 NM radius of the radar under conditions of ground
clutter,weather, angel clutter, interference, and ground vehicular traffic. The ASR-9
transmitter generates coherent RF pulses from a klystron amplifier.
The ASR-9 radar system is a dual channel radar with either channel, when
selected, working into a common antenna. One channel of the dual system is active
(radiating) while the standby channel is able to assume operational status upon
activation of a manual switch. The radar system is designed to operate continuously
and unattended over the specified range of service conditions[Ref.lO pp:l-2].
This ASR-9 equipment features a weather channel, moving target detector
(MTD), and built-in test equipment(BITE). The weather channel supplies the air
traffic controller with real time weather intensity data on his control display. A
separate weather channel is used to supply the standard National Weather Service
six levels of weather[Ref.l2 p:49]. Notable aircraft detection and false alarm control
improvements are achieved with MTD processing. The development of MTD has
increased the capability of ASR-9 in three areas : 1) detection of aircraft near the
airport over heavy ground clutter, 2)detection of aircraft in precipitation, 3)
resolution of closely spaced aircraft.
1. MTD (Moving Target Detection)
The MTD has been developed specifically to provide high quality,
interference-free data associated with air traffic control systems by the MIT Lincoln
Laboratory. Its implementation is based on the application of digital technology. In
addition to the MTI, doppler filtering, CFAR-type processing, and a number of
censoring techniques are used in the MTD processor.
Figure 2-1 shows a block diagram of the MTD system, which includes a dual
fan-beam elevation antenna. Transmission takes place through the lower beam;
It
t t
<
MAGNITUDE rGROUND
'
CLUTTER
RECURSIVE
FILTER
z g
3 9tU J:DC <E
si
r i H
K </) W3 £ 25 2 £K
HI 5
Figure 2.1 MTD Block Diagram
however signals are received through both the beams. The upper beam receives
echoes from close range targets with much less clutter from the ground. The lower
beam is used for distant targets. Although the antenna normally both radiates and
receives vertical polarization, whenever there is heavy precipitation over a significant
portion of the coverage, the radar switches to circular polarization. By doing so, the
sensor achieves an additional 12 to 20 dB of precipitation-echo rejection. During
operation with circular polarization, a switch located on the antenna selects either
the weather-channel upper or lower beam. The signal from the selected beam is
then passed through a signal rotating joint to the weather-channel receiver.
Signals for target detection pass from the antenna through a sensitivity time
control and a low-noise amplifier. After the signals are heterodyned to an
intermediate frequency, they are translated to baseband at the output of a linear
receiver. This step provides inphase and quadature video signals,which A/D converts
into digitized samples[Ref.l 1 p:364-365]. These samples are then processed in a three
pulse canceler and eight-pulse doppler filter bank, which eliminates stationary clutter.
The FFT filter bank with weighting is applied in the frequency domain to reduce the
filter sidelobes.
A target is declared when the signal crosses a constant false alarm rate(CFAR)
threshold. A report is generated for each target. Typically a target report consists of
range, azimuth, etc. Then the reports are correlated and centroids are found for the
range and azimuth measurements.
The MTD processor performs the following functions:
8
a. Signal Processing
Signal processing employs special-purpose hardware to cope with the
high data rate. Its functions include saturation/interference sensing,velocity domain
filtering, constant false alarm rate (CFAR) thresholding, clutter mapping for zero-
velocity target processing,and adaptive desensitization in mapped areas defining
visible roads and very large amplitude clutter. It can output over thirty thousand
primitive target declarations on each scan, the actual number depending on aircraft
traffic density, meteorological conditions, presence of birds, etc. An aircraft may
produce many primitive target reports per scan,depending on cross section,range, and
elevation.
The basic idea of the MTD signal processing is to break the radar coverage
into a large number of elemental range-azimuth velocity cells, and to select those
cells containing aircraft targets on instantaneous radial velocity and extent
characteristics of the real targets as compared to those of extraneous targets
including clutter. The ASR-9 MTD processor divides the range coverage(47.5 NM
in the original implementation) into 1/16 NM intervals and the azimuth into 3/4
degree intervals for a total 365,000 range-azimuth resolution cells.
D ; ;/ 47.5 NM 360 Degree ,,,,. AAAResolution cells = x 2 a 365,0001 3— NM — Degree16 4
Fig.2-2 shows how the MTD resolution cells are spread through the radar's range,
azimuth angle, and doppler coverage.
(
DOPPLER ( VELOCITY ) FILTERS4 5 6 7 12 J 4
r -62W 62 kt
CPI.
•C PULSES \
).__!_47.5 NM MAXIMUM
S RANGE
'n/18NM
s
Figure 2.2 MTD Resolution Cell
In each 3/4-degree azimuth intervalten pulses are transmitted at a constant
PRF. On receive, this is called a coherent processing interval(CPI). These ten pulses
are processed by the delay-line canceler and 8-pulse doppler filter bank(150 Hz
doppler bandwidth). Thus, the radar output is divided into approximately 2,920,000
range-azimuth-dopplercells(8 pulses x 365.000 range-azimuth cell = 2,920.000 )[Ref.l
p:127].
The three pulse canceler and the eight pulse doppler filter bank eliminate zero
velocity clutter and generate eight overlapping filters covering the doppler. Figure 2.3
shows the frequency response of the three pulse canceler and eight pulse doppler
filter bank.
L0
Clutter
spectrum
Double
cancellation
-62 kt(-600Hz)
PRF
62kt(600Hz)
Figure 2.3 The Frequency Response of the Three Pulse Canceler and the Eight
Pulse Doppler Filter Bank.
Sample
Transmitted intervals
pulses !__
m r^
Range resolution cell
21 2 3
_ 1 2 3FFT
1 2 3
„ 1 23i5i
1 2 3
71 2 3
R1 R2 R3 R4 Rm
FF0
I
I
I
....
iF1
I »e F3
y
I
fas I
F5 ...
... \~
...
F6
F7I
I
E1 2 3 Frequency
1 2 3
- TimeTest cell (13)
F3 1 2 3 4 5 6 7 8 9 1 11!12^14J 19 1^ 17 1 fl( 19 2<j) 2l| 2J 23 24 2$' * '\^\
Figure 2.4 The Matrix of Range Resolution Cell and Filter Number at CFARDetector
11
The MTD's central functional element is a set of doppler filters, typically 8 or
10 for each range ceil.The output of the filters are all individually subjected to
thresholds. Figure 2.4 shows the matrix of range resolution cells and doppler filter
bank at a CFAR detector.
The threshold for the nonzero-velocity resolution cells (in Figure 2.3 and Figure
2.4, the threshold for filters 2 through 6) are established by the mean-level based on
an average of the returns from the same Doppler cell in 16 range cells,eight on either
side of the cell of interest. This establishes constant false alarm rate(CFAR)
detection. In Figure 2.4, to determine the threshold of the range cell number 13 and
the filter number 3, the threshold is established by the mean of range cells 5 to 12
and 14 to 21. The threshold for zero-velocity resolution cells (in Figure 2.3 and
Figure 2.4, the threshold for filter 0) is determined by the average of the clutter
values that were observed in the subject range cell over 10 to 20 scans. The threshold
for filters 1 and 7 adjacent to the zero-velocity in Figure 2.3 are the greater of a
mean level threshold from the 16 range cells and a clutter threshold from the clutter
map.[Ref.l p:128-129]
To obtain acceptable performance in conditions of rain and ground clutter
interference, the MTD uses a set of eight finite impulse response filters for each
range cell. Two pulse repetition intervals are used to prevent the masking that occurs
when rain clutter obscures a target. The PRF's differ by about 20 %.
12
b. Correlation and Interpolation
The correlation and interpolation(C&I) processing correlates
primitive reports in the same scan that are associated with the same target using
range/azimuth adjacency, and interpolates to develop the centroid of measurement
variables(range, azimuth, velocity and amplitude). It also performs adaptive second-
level thresholding, and flags each target report with a quality/confidence indicator
before transmitting them to the third-level of processing(track filtering). The C&I
processing attempts to produce a single target report for each moving aircraft target
within the radar coverage, on each scan of the antenna, while adaptively limiting the
false alarms to fewer than 60 per scan.
c Scan-to-Scan Correlation and Tracking
The scan-to-scan correlation and tracking processing uses target
scan-to-scan history to "track" moving aircraft targets while filtering out those target
reports that are not associated with moving aircraft. Approximately 98 % of the
aircraft reports entering this processor are transmitted for display, while fewer than
one false alarm per scan are transmitted for display under most conditions.
2. Weather Channel
The weather channel provides superior performance by producing smooth,
stable contours of storm intensity. Unlike the weather data produced by MTI, the
ASR-9 contours are not biased due to the following factors: the sensor's circuitry,
circular polarization, antenna high-low beam selection, and sensitivity time control.In
13
ASR-9, a programmable range dependent threshold compensates for the above
factors and reduces the estimate bias that occurs from the partial filling of the radar
beam by the vertical extent of the storm.
Figure 2.5 contains a block diagram of the ASR-9 weather processor.
Q
1
2 _
1
2~"**
PRIMITIVE
DETECTIONS
CLUTTER
FILTER
BANK
FILTER
SELECTTHRESHOLD
SMOOTHING
AND
CONTOURING !
I _J
3 *4
3 5p
6
i i
CLEAR-DAY
CLUTTER
MAP
THRESHOLD
MEMORY
Figure 2.5 Block Diagram of the ASR-9 Radar Weather Processor
Digitized quadrature video signals pass through four parallel clutter filters:one all
pass and three notch type. A set of four filters effectively eliminates ground clutter.
The attenuating effect of these filters on storm echoes that have low radial velocities
is mitigated by a ground clutter map that was made on a clear day. The clear day
map can be used to select, on a range cell by range cell basis, the output of the least
attenuating filter for each desired weather level. Spatial and temporal smoothing
provides stable contours of precipitation regions.
14
III. DEPLOYMENT OF STANDOFF JAMMING AND JAMMING EQUATION
Noise jamming has the advantage against surveillance radars in that little need be
known about the victim radar's parameters except its frequency range[Ref.4 p:lll]. A
convenient classification of noise jamming is by the ratio of the jamming bandwidth to the
acceptance bandwidth of the victim equipment. If the ratio is large, it is called barrage
jamming. However if the ratio is small, then it is called spot jamming. The bandwidth of
barrage noise jammer extends over a large frequency band which includes the entire tuning
band of the radar. Barrage noise jammer bandwidth is typically 10% of the radar RF
frequency extending over several hundred megahertz.
The operational categories of jamming include escort jamming, self-protect jamming,
stand-off jamming. Only standoff jamming is discussed in this.
A. STANDOFF JAMMING TACTICS AND DEPLOYMENT
The stand-off jammer on a heavier and slower platform can carry a higher power
jamming transmitter and a higher gain antenna as compared to an attack aircraft[Ref.2 p:
6]. The ERP of a single transmitter/antenna combination may be in the range of +50 dBW
to + 100 dBW. This high ERP overcomes the propagation loss of a larger jammer range and
enables it to inject jamming power through the radar antenna's sidelobes. Several
transmitters may be aboard a single aircraft, with one or more of the transmitters dedicated
to jam a given type or class of radars(e.g.,surveillance,tracking,or imaging radars) [Ref. 13
p:12-4].
15
Usually, the jamming aircraft may orbit an elongated racetrack course,the long axis
of which is normal to the line-of-sight(LOS) to the area targeted for jamming behind the
forward line of troops(FLOT),and transmit from one of two antennas toward the victim
radars. With two or more jamming aircraft simultaneously on orbit, one can cover for the
other as the latter executes the turn at either end of the racetrack[Ref.2 p:2]. A typical
stand-off radar jammer employs an ESM system with direction finding capability to locate
threat radars.
B. JAMMING EQUATIONS
In this section we develop the equations for standoffjamming. A standoff jammer can
jam either through the mainbeam or the sidelobes of victim radar's antenna to reduce its,
detection range. Both cases will be considered. The calculation depends upon finding the
change in radar signal-to-noise ratio(SNR) due to the jamming. A reduced SNR would result
in a smaller detection range as compared to the normal detection range of the radar.
1. Mainbeam Jamming
a. Radar Range Reduction
The signal to interference(S/I) at the CFAJR detector in the presence
of a jammer will depend upon radar and jammer parameters and can be written as
Id
s4_s_
I ~ J+N
where
S is target signal power
J is jamming power
N is thermal noise
S/I in the above equation can be written in two ways as
(3.1)
5 1
/ 1+J
s+
s
N
S
S _ NI I, I
(3.2)
(3.3)
.V
In this thesis, the second method for radar range reduction is considered. It may be noted
that S/N is normal SNR at the CFAR detector. This quantity can be computed by using
normal radar range equation.
By taking 10 log of Equation 3.3 it can be rewritten as
A .A -(Z + i)
< 3 -4 )
17
and rearranging
A .A =f2 +n (35)
It may be noted that the left hand side of the above equation represents a loss in
radar signal-to-noise ratio (in dB) due to jamming. Thus the decrease in S/N can be
determined by computing (1+ J/N)dB . This loss of (1 + J/N)dB in the normal SNR due to
jamming can be represented as reduction in detection range. J/N can be determined by
computing jammer power and thermal noise in the radar receiver.
Jammer power J in the mainbeam is given by
P. G, GrX2
B, (3 -6 )
J= J J r(-^) K.
(4**/ L. Bj
where
Pj is jammer power in watts
Gj is jammer antenna gain
LJ
is jammer loss
Rj is radar range to jammer
Br
is radar bandwidth
Bj is jammer bandwidth
Kj is jammer waveform gain in the radar signal processor
IS
Receiver thermal noise N is given by
N = k T F Br
(3.7)
where
k is Boltzman's constant of magnitude 1.38 x 10"23
T is room temperature of 290°F
F is radar receiver noise figure
From Equation 3.6 and 3.7, J/N is given by
j_P_iGiGi
X_i B,
K (3.8)_
N (4nRp2 Lj kToB
rF B
J'
It may be noted that the above equation is valid only for noise jammers (not, for
example, for coherent jammers which will have some processing gain).
Loss in radar SNR due to jamming is computed as
J N
L9
The maximum radar detection range(R2 ) under jamming conditions is given by
*2=
(T-)4
*1(3.9)
where
Rj is maximum radar detection range under normal conditions.
R2
is maximum radar detection range under jamming conditions.
The following table shows examples of range reduction for assumed losses.
Loss(dB) Lj (1/ Ljr Range reduction
1 1001 = 1.259 0.94 6 %
2 10° 2 = 1.585 0.89 11 %
3 1003 = 1.995 0.84 16 %
5 lO05 = 3.162 0.74 24 %
10 101 = 10 0.56 44 %
15 1015 = 31.62 0.42 58 %
20 102 = 100 0.31 69 %
b. Burn-through Range
In free space the radar echo power returned from a target varies
inversely as the fourth power of the range, while power received at the radar from a jammer
varies inversely with the square of the target range. Therefore, as range decreases, radar
20
echo power from the target increases more rapidly than does received energy from the
jammer. Inevitably a point is reached where the energy received from a noise jammer is no
longer great enough to hide the target echo. This range is called the burn-through
range[Ref. 14 p:54].
To compute the burn-through range we need to compute J/S first. The signal power
into the radar antenna is given by
PtG, G
ra A
2(3 10)
S = ''
r PCR Nn
{ ;
(4k) 3(/?/ L
s
P
where
Pt
is peak transmitter power in watts
G, is transmit antenna gain
Gr
is radar antenna gain
a is target radar cross section
Ls
is signal loss in the radar
RT is radar range to target
X is radar signal wavelength
PCR is pulse compression ratio
Np
is Number of pulses integrated (FFT gain)
21
Jammer power J in the radar receiver through the mainbeam of the radar antenna is given
by
P. G, G X 2 Br (3 in
j=_j_j_r— ^ K p-ii;
(4*/y2 L
}
B.
It may be noted that Br/Bj does not exceed unity even if Bj is less than B
r. Therefore, J/S
can be written as
J _PjGj 4* Vtf *r Kj k (3.12)
S~ PtG
to (Rp2 Bj PCR N
pL
}
Burn-through range from above can be written as
_ P.G, ojtf B, PCRNp
L, j I (3.13)
PjQj 4n Br
Kj Ls
S
(J/S) in the above equation is computed from the specified probability of detection.
2. Sidelobe Jamming
a. Radar Range Reduction
When the stand-off jammer jams through the sidelobes of the victim
radar's antenna, it suffers a disadvantage equal to the radar's mainlobe to sidelobe gain
ratio. The effect of sidelobe jamming on the radar performance can be determined in the
same manner as for the mainbeam jamming case except for the computation of jammer to
22
noise (J/N) ratio. The sidelobe jammer power J in the receiver of the victim radar is given
by
P G G, X2
1 Br
J = J'
sl — (^) AT (3.14)
(4**/ L. SLC B. >
where
Gsl
is sidelobe gain of radar receiver.
SLC is sidelobe cancellation ratio if any.
If Br< Bj , then B
r/Bj = B
r/B
r
If B,. > Bj , then B^Bj = 1.
Ki
is jammer signal processing gain if any. It will be unity for noise jamming.
J/N can be written as
j_ _ P. GJG
slX2
1 _J_B,
K (3.15)
N (4k*.)2
Lj kToB
rF SLC B.
J
Therefore, range reduction can be computed using Equation 3.9.
b. Burn-through Range
The signal power into the radar receiver is given by
P,G,G a X2
S =f
'r PCR N (3.16)
(4tt)3 (Rt)
4 Ls
p
23
Sidelobe jamming power J in the radar receiver is given by
P. G. G, X 2 Br1 J 5l— (— ) K.
(4n/?/ Lj Bj
*
(3.17)
J/S for the sidelobe jammer at the CFAR detector can be written as
l - li2i in {liL h 5 h 3* < 3 - 18 )
S' P
tG
to (*/ Bj PCR N
pL. G
r
From above, burn-through range can be written as
P,G, o (*/ B, PCRNp
I, G, ,i (3.19)
(J/S) in the above equation is computed from the specified probability of detection.
24
IV. THE EVALUATION OF ASR-9 RADAR PERFORMANCE
In this chapter, the ASR-9 radar and the jammer parameters are specified. The radar
probability of detection is determined as a function of target(to radar) range without
jamming. Then the same computation is performed with both mainbeam and sidelobe
standoff jamming. Both barrage and spot noise jamming are considered. Burn-through
ranges are determined for both mainbeam and sidelobe jamming.
A. ASR-9 RADAR AND JAMMER PARAMETERS
1. ASR-9 Radar Parameters
ASR-9 radar has the following parameters.
Peak power ( P, )= 1200 kw (60.79 dBW)
Antenna Gain ( G = G, = Gr )
= 33.5 dB
Sidelobe gain of radar receiver ( G sl )= 3.5 dB
Radiated Frequency ( f )=2.9 GHz
Wavelength(A) = 10.35 cm (10.15 dBcm)
Pulse Width ( r )= 1.05 yus
Antenna Azimuth Beamwidth ( 6 )=1.3 degree
Rotation Rate = 12.5 rpm
Scan rate = 75 degree/sec
Pulse Repetition Frequency( PRF )= 1200 pps
Noise Figure ( F)
= 5 dB
25
Target radar cross section ( a )
Doppler bandwidth ( BDopp )
Pulse Compression Ratio( PCR )
Probability of detection ( PD )
Probability of false alarm ( PFA )
Total system Losses ( L )
System losses are broken down as follows
Transmitter
Receiver
Mismatch
Integrator
Collapsing
Beam shape
MTI
= 1 m2(0 dBsm)
= 150 Hz
= OdB
= 0.9
= 10"6
= 12 dB
= 2dB
= 2dB
= 1 dB
= 1 dB
= 1 dB
= 3 dB
= 2dB
Radar bandwidth(B)
Number of pulses(n)
Integration efficiency(E1
(n))
Elevation Beamwidth ( -3 dB)
= 9.52 x 105 Hz (59.8 dBHz)
= (beamwidth/scan rate) x PRF
= 21 (13.22 dB)
= 1 for coherent integration
= 4.8 degree (minimum)
26
2. Jammer Parameters
Assume jammer parameters as given below
Jammer ERP = 20 dBW
Range between standoff jammer and radar( Rj )=50 NM
Jammer loss( Lj )= dB
Jammer bandwidth( Bj ) ;
Spot noise jamming = 10 MHz
Barrage noise jamming = 300 MHz
Jammer signal processor gain( K^ )= dB
Radar sidelobe cancellation ratio(SLC) = dB
B. MATHEMATICAL EVALUATION
1. Radar Performance Evaluation without Jamming
Radar performance under normal conditions is usually computed using
professionally written computer programs, but the basic steps of the computation are
outlined in this section. Maximum detection range for ASR-9 will be determined by
coherently integrating the pulses over one scan.
For target model case l(swerling 1), the echo pulses received from the target on any
one scan are of constant amplitude throughout the entire scan, but are independent from
scan to scan.
27
a. For case 1, PD , and PFA are related by
(£>, i (4.1)
which can be rewritten as
S log PFA
(£), = -±-? - 1 (4.2)N log PD
where (S/N)j is single pulse SNR required to achieve stated PD and PFA .
With PD = 0.9 and PFA = 10"6, (S/N^ = 130.13 (21.1 dB)
b. Maximum detection range(Rmax ) is given by
4P
tG 2
X2 a n Ejji) PCR
(4tt)3(-), k T B F L
(4.3)
Equation 4.3 can be written in logarithmic form in mixed units as given below
4(R)dBnm - (Pt )dBw + 2(G)dB + 2(A)dBcm + (a)dBsm + (n E,(n))dB - (S/N)
1 dB- (B)dBHz
- (F)„ - (L)dB + 0.3 (4.4)
c. Substituting the values of radar parameters in the left hand side
4(R )dBnm = °0-79 + 2 x 33.5 + 2 x 10.15 + + 13.22 - 21.14 - 59.8 -5-12 + 0.3
= 63.67
and therefore
R max = 39.05 NM
d. Thus, the maximum detection range of ASR-9 under normal conditions (for case
1 RCS model with PD of 0.9 and PFA of 10-6
) is 39.05 NM.
28
e. From Equation 4.2 and 4.3
4P
tG2
X2a n Efn) PCR
(4U )3 (fe FA
-\) kT B F L(4.5)
f. Equation 4.5 gives Rmax for any PD . Using this equation to plot PD vs range results
in Figure 4.1. Previously defined radar parameters of ASR-9 are used with PD as a variable
parameter. It can be seen from the Figure 4.1 that as PD increases, the detection range
decreases, which is expected.
0.8
c.0
T>V"D
0.6 -
o
o
Cl
0.4
0.2 -
20 40 60 80
Range (NM)
100 120 140
Figure 4.1 The Probability of Detection vs Target Range for ASR-9 without Jamming
29
Figure 4.1 also shows the 39.05 NM maximum range at 0.9 probability of detection without
jamming.
2. Radar Performance Evaluation with Mainbeam Jamming
a. Maximum Detection Range with Barrage Jamming
To compute radar detection range in jamming, first compute J/N
j P. G. G X2
1 B- = J J
' (— ) (4.6)N (4nRp2 L. kT
oB
rF B
j
The logarithmic form of the equation is as follows
(J/N)dB = (ERPj)^ + (Gr)dB + 2(A)dBm - 2(R
J)dBm + (B
r) Hz- (B^ - (Lj)dB
- (Br)dB - F'
+ 181.993 (4.7)
By substituting radar and jammer parameters
(J/N)dB = 20 + 33.5 + 2(-9.85) - 2(10 log(1852 x R^) - 84.77 - 5 + 181.993
= 126.02- 20 log( 1852 x Rj) (4.8)
The loss in SNR due to jamming is given by
l = i + Jl = i + ioJ N
30
The radar detection range(R2 )
under jamming conditions is
*2 ifr «. (4.10)
/here
R{
is maximum radar detection range under normal conditions(without jamming).
R, is maximum radar detection range under jamming conditions.
0.6 ' ^^~-
•v.CNIK
"flf
co
0.5
0.4
^^^^^
c
<v
(V
Q0.3 y^
5oen 0.2
"5
Eoz
0.1
(
- /
) 50 100 150 200 250 300 350 4()0
Standoff Jammer Range(NM)
Figure 4.2 Normalized Radar Detection Range(R2/R
1) vs StandoffJammer Range(Rj) for
the Mainbeam Barrage Jamming.
Using Equations 4.8,4.9 and 4.10, normalized radar detection range(R2/R
1 )is plotted
as a function of radar range to jammer(R). Figure 4.2 shows a normalized detection range
31
of 0.22 at 50 NM of radar range to jammer. Thus normal radar detection range is reduced
by factor of 78 %. For the specific case of PD = 0.9, Rj = 50NM the detection range R2
under jamming is obtained as
R2= 0.22 x R,
= 8.40 NM (for R{= 39.05 NM)
1
'••., —•-^ Jammer bandwidth:300 MHz'
Jammer ERP:20 dBWJamming range:50 NM
0.3
Mainbeani omm'tnq \
RCS:Case 1
-
c,0
0.5 -
o
>~
15 0.4 _\No jamming
OCl
0.2
0_
-
) 20 40 60 80 100
Range (NM)
120 140
Figure 4.3 The Probability of Detection vs Target Range for ASR-9 with MainbeamBarrage jamming.
To determine the detection range under jamming and all values of PD for radar to
jammer range of 50 NM, the following formula can be used
32
P, G 2I2 o n E<n) PCR \
R2
= 0.22 x ('- '
)
4
^gPFA __/ (4.H)(4ny ( -1) kT B F L
^gPD
For the assumed radar parameters, the results are plotted in Figure 4.3.
b. Maximum Detection Range with Spot Jamming
Spot noise jammer parameters are as follows.
Bandwidth = 10 MHz
Jammer ERP = 20 dBW
Jamming range = 50 NM
By substituting radar and jammer parameters in Equation 4.6, the ratio (J/N)dB is
(J/N)dB = 20 + 33.5 + 2(-9.853) - 2(10 log( 1852 x R)) - 70 - 5 + 181.993
= 140.79 - 20 log(1852 x K) (4.12)
Using Equations 4. 12,4. 9,and 4. 10, a graph of normalized detection range(R2/R
1) vs jamming
distance(Rj) is constructed. Figure 4.4 shows 9 % at a 50 NM range to jammer.
33
0.3
\ 0.25
I 0.2
- —~
Detection
o -
-5
2 0.1
o
"5
E 0.05o-z.
//
(
,,
) 50 100 150 200 250 300 350 400
Standoff Jammer Range(NM)
Figure 4.4 Normalized Radar Detection Range vs Standoff Jammer Range for the
Mainbeam Spot Jamming
For the specific case of PD = 0.9 , PFA = 10"6 and Rj = 50NM, the detection range R2under
jamming is obtained as
R2= 0.09XRJ
= 3.59 NM
34
To determine detection range under jamming for all values of PD , use the following
formula
P, G2X2a n E,(n) PCR \
FL = 0.09 x ('- '-
)
4
(4U )3 (_f_K*_i) k T B F L(4.13)
The results are plotted in Figure 4.5.
Jbmmer bondwidth:10 Mri;
Jammer ERP:20 dBWJamming range:50 NMRCS:Case 1
60 80
Range (NM)
140
Figure 4.5 The Probability of Detection vs Target Range for ASR-9 with Mainbeam Spot
Jamming.
35
c. Bum-through Range and Crossover Range
The range at which the radar and jammer powers are equal (J/S = 1)
is often referred to as the jammer crossover range. The term "burn-through range" has been
generally used to denote a range at which targets can be detected more reliably than
indicated by crossover range. In this thesis, the range at which target can be detected with
a 50 % probability of detection in the presence of jamming will be called " burn-through
range ".
These ranges are calculated for mainlobe jamming from the following equation
PGt
o (R,)2
B, PCRNn L. j \R = (_!_i _lil _1 £ _! (£))4 (4.14) .
PJG
J4* B
rK
}L
sS
In logarithmic form
4RB = (Pt)dBw + (Gt)dB - (Pj)dB - (Gj)dB + (a)dBsm + 2(R
J)dbm - 10.992 + (B^ - (B
r)Hz
+ (PCR Np)dB
-(Kj)dB +(Lj)<fB
-( Ls )dB + (J/S)dB (4.15)
Substituting the relevant radar and jammer parameters( with jammer bandwidth of 300
MHz, J/S = 1) in the above equation
(Rc)dB = (60.79 + 33.5 - 20 + 2(49.67) - 10.99 + 24.99 + 13.22 - 12)/4 = 47.21 dB
Rc = 52,632 m = 28.42 NM for the mainlobe jamming.
36
Now compute J/S required for 50 % probability of detection(PD ). From Equation 3.2,
in the presence of jamming
1 = J_ - _L5 5 5_ (4.16)
/ N
where S/I is signal-to-interference ratio required for PD of 50 % and S/N is signal-to-noise
ratio for PD of 90 %. Solving gives
I log PD1 (4.17)
For PD = 0.5 and PFA = 10"6, S/I = 18.93. From Equation 4.2, the SNR under normal
conditions(PD = 0.9, PFA = 10"6) was computed before as 130.13. Substituting the values
of S/N and S/I in Equation 4.16, gives
- = —— - —— = 0.045 (4.18)5 18.93 130.13
Substituting this value of J/S in Equation 4.15, we obtain RB = 43.85 dB which gives
R B = 24,246 m or 13 NM for the mainbeam jamming.
37
3. Radar Performance Evaluation with Sidelobe Jamming
a. Maximum Detection Range with Barrage Jamming
For sidelobe barrage jamming, compute J/N(for B- of 300 MHz) as
follows
j P. G, G . X2
1 B- = ] J sl(-^) (4.19)
N (4tc/?/L. kToB
rF B
j
The logarithmic form of the equation is
(J/N)dB = (ERPp.Bw + (Gsl)dB + 2(X)dBm - 2(R
J)dBm + (B
r ) Hz- {B)Hz
- (L^ - (Br)dB - F
+ 181.993 (4.20).
By substituting radar and jammer parameters, we obtain (J/N)dB as given below
(J/N)dB = 20 + 3.5 + 2(-9.85) - 2(10 log( 1852 x R})) - 84.77 - 5 + 181.993
= 96.02- 20 1og(1852x R^ (4.21)
The loss in SNR due to jamming is given by
(— )dB
(4.22)
(— )dB
f'l-- \U - -- 1+10 10
N
38
Therefore, the radar detection range(R2 )
under jamming is
«2 (-/->' «.(4.23)
20 40 60 80 100 120 140 160 180 200
Standoff Jammer Range(NM)
Figure 4.6 Normalized Radar Detection Range(R2/R
1 )vs Standoff Jammer Range(Rj) for
the Sidelobe Barrage Jamming.
The normalized radar detection range is determined using Equation 4.21, 4.22 and 4.23. For
the specific case of Rj = 50 NM the detection range R2under jamming is
39
R, = 0.91 x R,
= 35.54 NM (for R, = 39.05 NM)
1 J-*,-^>^^ Jammer bandwidth:300 MHz1
v
\\ Jammer ERP:20 dBW
\\ Jamming range:50 NM
0.8Sidelobe gain:3.5 dB
RCS:Case 1
c \ \o \ \
0.6 N
"ON
Sidelobe
_>v jamming \ \
!5 0.4 -\ \No jamming
.QC \ \£ s \
0.2
i i r-r n
c? 20 40 60 80 100
Range (NM)
120 140
Figure 4.7 The Probability of Detection vs Target Range for ASR-9 with Sidelobe
Barrage Jamming.
To determine detection range under jamming for all values of PD for a radar to
jammer range of 50 NM, use
40
PtG2
k2a n Ein) PCR \
*> - °'9' * (
3lOSPFA
)4(4.24)
(4^)3 (
& FA-\) kT B F L
^gPD
For given radar parameters, the results are plotted in Figure 4.7.
b. Maximum Detection Range with Spot Jamming
Next,let us consider sidelobe spot jamming with the jammer parameters
of bandwidth of 10 MHz, jammer ERP of 25 dB, jamming range of 50 NM in the equation
/ P. G, G . X 21 B
r- = ' J slt (-^) (4.25)
N (4^)2
L. kToB
rF B
j
The logarithmic form of the Equation 4.25 is as follows
(J/N)dB = (ERPp^w + (Gsl )dB + 2(A.)dBm - 2(R
J)dBm + (B
r ) Hz - (B^ - (L^ -(Br )dB - F
+ 181.99 (4.26)
By substituting radar and jammer parameters in Equation 4.26
(J/N)dB = 20 + 3.5 + 2(-9.85) - 2(10 log(1852*Rj)) - 70 - 5 + 181.993
= 110.79 - 20 log(1852*Rj) (4.27)
Using Equations 4.27, 4.9 and 4.10, a graph of normalized radar detection range
(R^/Rj) vs jammer range(Rj) is plotted in Figure 4.8. This Figure shows a normalized
detection range of 51 % for standoff jammer at 50 NM.
41
0.9 1 ' '
1
£> 0.8 .
s\CNCC 0.7 _ _
0>
o>coOS
0.6 -
co
o 0.5 -
_0>
"53
QD
0.4' /
0.3" /
0>
0.2 /E
/o2 0.1
/
/
Q
20 40 60 80 100 120 140
Standoff Jammer Ronge(NM)
160 180 200
Figure 4.8 Normalized Radar Detection Range vs Standoff Jammer Range for the
Sidelobe Spot Jamming.
For PD = 0.9 , PFA = 10"6 and Rj = 50NM, the detection range R2under sidelobe jamming
is obtained as
R2= 0.51x1*!
= 19.85 NM
To determine detection range under jamming for any value of PD
#2 = 0.51 x (
PtG 2
X2 a n Effl) PCR
1) k T B F L(4.28)
42
:.e
0.5
0.4
0.2 -
Jammer bandwidth:l0 Ml^z
Jammer ERP:20 dBWJamming range:50 NMSidelobe gain:3.5 dB
RCS:Case 1
Sidelobe jamming
o jamming
20 40 60 80
Range (NM)
100 120 140
Figure 4.9 The Probability of Detection vs Target Range for ASR-9 with Sidelobe Spot
Jamming.
For given radar parameters, the results are plotted in Figure 4.9.
c. Burn-through Range and Crossover Range
Using the appropriate J/S, crossover range and burn-through range for
sidelobe jamming can be determined from the following equation
_ AG, M^ B, PCRNp
L, G, j \
PJQ 4k B
rKj L, G
slS
(4.29)
43
The above equation can be written in logarithmic form as follows
4RB = (Pt )dBw + (G
t )dB - (ERP)dBW + (a)dBsm + 2(1^ - 10.992 (B^ - (Br ) IIz
+ (PCR Np )dB
- (Kj)^ + (Lj)dB - ( Ls )dB + (Gr)dB - (G
sl )dB + (J/S)dB (4.30)
Substituting the relevant radar and jammer parameters(jammer bandwidth of 300 MHz and
J/S = 1)
(Rc)dB = (60.79 + 33.5 - 20 + 2 x 49.67 - 10.99 + 24.99 + 13.2 - 12 + 30)/4 = 54.71 dB
which gives the crossover range for the sidelobe jamming case
Rc = 295,631 m = 159.6 NM
To compute burn-through range, a value of J/S for PD of 0.5 is required. This was
obtained as 0.045 earlier in this section. By substituting this value of J/S in logarithmic form
in Equation 4.30 , a burn-through range(R B ) of 73 NM is found for the sidelobe jamming
Figure 4.10 shows the plot of signal and jamming power levels(both mainbeam and
sidelobe) vs range. Signal power is computed from Equation 3.10. Mainbeam and sidelobe
jamming powers are computed from Equations 3.11 and 3.14. It should be noted that both
are at fixed range of 50 NM. Figure 4.10 can be used to determine crossover range and
burn-through range for a specified J/S. For example, the burn-through range for mainbeam
jamming for J/S of -10 dB is 16 NM from Figure 4.10.
44
ERP : 20 dBW
100 -w Target signal Jamming bandwidth : 300 MHz
^\^ Range to jammer : 50 NM-
110 -Nv Mainbeam Jamming signal
-
120 - -
130 -
140Sidelobe Jamming signal ^^\^
_
150 -
160 -
170
1 An
- \-
10 1 102
Range (NM)
103
Figure 4.10 Burn-through Range of Mainbeam Jammer and Sidelobe Jammer.
45
V. ECCCM FEATURES
The primary goal of noise jamming of the ASR-9 is to prevent target detection and
acquisition. ECCM techniques that can reduce the radar vulnerability to each type of
jamming are summarized in the Table 5.1.
Jamming Type Effects of jamming ECCM Techniques
Mainbeam jamming
* Barrage Prevent target detection Jammer strobe processing
* Spot
and acquisition Coherent integration
Prevent target detection Same as barrage jamming,
and acquisition, receiver plus frequency agility, wide
saturation dynamic range receivers
Sidelobe jamming
* Barrage Prevent target detection Low sidelobe antennas,
and acquisition sidelobe cancellation or
blanking, coherent
* Spot
integration
Prevent target detection Same as barrage
and acquisition noise(sidelobe),plus
frequency agility
46
A. ECCM FOR MAINBEAM JAMMING
The noise jammer situation is basically an energy battle between the radar and the
jammer. For mainbeam noise jamming, the advantage is with the jammer because the radar
experiences a two way propagation loss of its energy as contrasted with the one way
propagation loss between the radar and jammer. Thus, mainbeam jammers provide strong
beacon like signals that betray their angular locations, which then can be exploited by the
radar in weapon designation. If the radar is netted with other radars, the jamming target can
be located through triangulation.
With mainbeam noise jamming, the radar design principles are clear.
1. The radar must maximize the energy received from the target with respect to*
that received from the jammer
It can maximize the received target energy by transmitting more average
power, dwelling longer on the target, or increasing antenna gain. If the radar's data rate is
fixed and a uniform angular search rate is dictated by mechanical or search strategy, then
the only option for the radar is to increase its average transmitter power. The next option
is to reduce the data rate requirement, thereby allowing a longer dwell time on the target.
2. The second principle of ECCM design in mainbeam noise jamming is to
minimize the amount of jamming energy accepted by the radar
This is accomplished by spreading the transmitted frequency range of the radar
over as wide a band as available while maintaining a radar bandwidth consistent with the
radar range resolution requirement. For example, if a 150 to 300 MHz transmitting
47
frequency range is available at S band for a 1 MHz radar resolution bandwidth, then the
potential for a 150 to 300 dilution of the jamming energy is possible. The ECCM objective
is to force the jammer into a barrage jamming mode of operation. Operation of radars over
a wider bandwidth than that dictated by range resolution requirements can be accomplished
in several ways. Some radars incorporate a spectrum analyzer which provides an advance
look at the interference environment. This allows the radar frequency to be tuned to that
part of environment which contains minimum jamming energy. This can be defeated if the
noise jammer has a look-through mode and can follow the radar frequency changes[Ref.4
p:222-223].
a. Frequency Agility
Frequency agility is the ability of the radar to transmit pulses of single
frequency with a narrow bandwidth which can be changed from pulse to pulse. The purpose
of this technique is to spread the jammer power over a wide band and thus dilute its
spectral density. Frequency hopping by the radar is usually performed on a pulse to pulse
basis for non-coherent modes and on a dwell to dwell basis when dwells are coherently
processed. For an MTI radar, this period may be as short as every two transmitted
pulses,and typically every three or four transmitted pulses. For pulsed Doppler radars, a
block processing interval will consist of many pulses. Frequency agility forces a noise
jammer into a barrage-jamming mode. Apart from ECCM benefit of frequency agility, it
also reduces glint error, eliminates multiple time around echoes and decorrelates clutter.
48
b. Frequency Diversity
This is the ability to operate radars at a wide and diverse set of
frequencies forcing the ECM system to provide a diversity equal to that used in the radar.
Thus, frequency diversity uses several complementary radar transmissions at different
frequencies, either from a single radar or several radars. The radar can operate in an
integrated manner utilizing all the resources to the maximum extent. The diversity is usually
limited by practical considerations to a finite number of frequencies(five to ten). Examples
of this mode of operation are a 2-D surveillance radar coupled to a height-finder radar at
a different frequency, or a number of spatially dispersed radars in a netted configuration at
different frequencies.
c Coherent Integration
Coherent integration narrows the receiving bandwidth and thus reduces
the effectiveness of noise jamming.
3. The third method which is employed to reduce the effect of mainbeam noise
jamming is to narrow the antenna's beam
This restricts the sector which is blanked by mainlobe noise jamming and also
provides a strobe in the direction of the jammer. Strobes from two spatially separated radars
pinpoint the jammer's location. However,with multiple jammer ghosting can be a problem.
B. ECCM FOR SIDELOBE JAMMING
The ECCM design principles for mainlobe noise jamming also apply to sidelobe noise
jamming, with the exception that the sidelobe response in the direction of the jammer also
49
must be minimized. Barrage noise produced by a sidelobe jammer can deny detection and
acquisition of a quiet target within the radar mainbeam, and can significantly degrade
detection if directed at the radar sidelobe region. The following methods are used to reduce
the vulnerability of radar to the sidelobe jamming.
1. Low Sidelobe Antennas
For those situations in which the jammer operates through the victim radar's
receiving antenna sidelobes, reduction of the sidelobe gain will directly reduce the
effectiveness of the jamming. A radar with only 20 dB sidelobes can easily be made useless
over 360 degrees by a standoff noise jammer. Even its ability to obtain azimuth information
on a jammer is impaired. Thus, low sidelobes are the first defense to combat standoff
jamming[Ref.5 p:60]. Significant reduction of the sidelobe level can be achieved through
the use of a suitably tapered illumination function across the receiving antenna aperture.
2. Sidelobe Blanker
The block diagram is given in Figure 5.1. The omnidirectional auxiliary
antenna must have a gain of 3-4 dB above the sidelobes of the main antenna. When the
signal in the auxiliary channel is more than the signal in the main channel then the signal
must have entered through the sidelobe. In this case the gate is opened preventing the
jamming signal from entering the receiver and display. Sidelobe blanker is effective only for
low duty cycle pulse or swept frequency jamming. It should be noted that targets in the
mainbeam are also discarded when blanking is done.
50
ONMI
V VCOMPARATOR
GATE
Figure 5.1 Sidelobe Blanker Block Diagram
3. Sidelobe Canceler
A coherent sidelobe canceler is a form of adaptive array antenna that uses a
small number of elements to adaptively place nulls in the direction of jamming signal. This
is a complex task and it requires at least one auxiliary antenna mainbeam loop for each
jammer. A simplified block diagram is given in Figure 5.2. Present SLCs have the capability
of reducing sidelobe noise jamming by 20 dB, but their theoretical performance is quoted
much higher.
One of the limitations of the SLC is that the number of degrees of freedom is usually
low, since only a small number of auxiliary antennas can be practically added to the main
antenna. Because the maximum number of sidelobe jammers which can be handled is equal
to the number of auxiliary antennas, the cancellation system is easily saturated. This
problem is compounded by any jammer multipath from objects in the proximity of the radar
51
T^JT
fs DESIRED SIGNAL JAMMING SIGNAL
If) ^-~-<I\\§&' f\\yi/ v^y yk
; AUXHJARY
T CHANNELS
Wi (9) • •
w 2 (g)
W k ^)
^ + X" '\-~
^£-J,-sL
Figure 5.2 A Simplified Block Diagram of Sidelobe Canceler
which add an additional degree of freedom for each multipath signal having an angular
direction significantly different than that of the main jammer. Another complication occurs
for antennas whose cross polarization response is significantly different than its main
polarization response. This causes two orthogonally polarized auxiliary antennas to be added
for each degree of the SLC system.
52
VI. CONCLUSION AND RECOMMENDATION
This thesis describes the evaluation of radar performance degradation due to standoff
jamming on surveillance radars. To keep the study unclassified, civilian radar ASR-9 was
used as a victim radar. Jammer parameters representative of real life jammers were
employed in the study. The maximum detection range of ASR-9 radar was evaluated for
various cases. First of all PD was determined as a function of target range without the use
of jamming. Then PD was determined as a function of target range with the standoff
jamming. Both mainbeam and sidelobe jamming were considered. In each of the above two
categories the performance degradation due to both barrage and spot jamming was
determined.
As illustrated in chapter four, the barrage jamming through the radar antenna's
mainbeam reduces the maximum detection range by factor of 78% of the normal detection
range. Spot jamming through the mainbeam has 91% range reduction. Similarly, barrage
jamming through the sidelobes has 9% range reduction and spot jamming through the
sidelobes has 49 % range reduction of the normal maximum detection range. Thus, the
mainbeam spot jamming is more effective as compared to the other jamming cases.
The Figure 6.1 show the maximum detection range under barrage jamming through
the mainbeam, spot jamming through the mainbeam, barrage jamming through the
sidelobes, spot jamming through the sidelobes and no jamming condition. For constant
jammer ERP, mainbeam jamming is more effective than the sidelobe jamming and the spot
jamming is more effective than the barrage jamming.
53
0.6 -
0.4-
0.2 -
<— tVloinbecn-^ Spot
\\<— Moinbspm Barrage \
'RCS:Case 1
'
Jammer ERP:20 dBWJamming ronge:50 NMSidelobe gain:3.5 dB
BW:Spot:10 MHzBarrage:300 MHz
^ -Sidelobe Barrage
.< — No Jamming
60 80
Range (NM)
140
Figure 6.1 The Probability of Detection vs Target Range for ASR-9 with Mainbeam and
Sidelobe jamming.
54
APPENDIX. A COMPUTER PROGRAMS
1. MATLAB PROGRAM FOR THE PROBABILITY OF DETECTION WITH/WITHOUT
STANDOFF JAMMING
x = 0.001:0.01:l;
bl=ones(100);
b2=bl(l,:);
b3 = (loglO(l(T(-6))).*b2;
b4=10.*b2;
al=b3./logl0(x);
a2 = 10*logl0(al-l);
a3 = (84.81-a2)/40;
a4 = b4.~a3;
cl =0.092. *a4;
c2 = 0.22.*a4;
c3 = 0.91.*a4;
c4=0.51.*a4;
plot(cl,x,c3,x,a4,x,c4,x,c2,x)
xlabel('Range (NM)')
ylabel('Probability of dection ')
text(100,0.95,'RCS:Case 1')
text(100,0.9,'Jammer ERP:20 dBW)text(100,.8,'Sidelobe gain:3.5 dB')
text( 100,0.85,'Jamming range:50 NM')text(100,0.75,'BW:Spot:10 MHz')text(106,0.7,'Barrage:300 MHz')text(5,0.7,'<-Mainbeam Spot ')
text( 13,0.6,' <-Mainbeam Barrage')
text(32,0.5,' < -Sidelobe Spot')
text(6 1,0.4,' < -Sidelobe Barrage')
text(73,0.3,' < -No Jamming')
meta tfig61
55
2. MATLAB PROGRAM FOR BURN-THROUGH RANGE
x= 18520:1000:1852000;
a = 76.3277-40*logl0(x);
b = -112.2974;
d = -142.2974;
c=x/1852;
for z= 1:1834;
zl(z) = l;
bl=zl;
end
b2 = bl(l,:);
cl = b.*b2;
c2 = d.*b2;
semilogx(c,a,c,cl,'-.',c,c2,':');
xlabel('Range (NM)');ylabel('Power at Radar Receiver (dB)')
text(15,-100,'Target signal')
text(40,-110,'Mainbeam Jamming signal')
text(20,-140,'Sidelobe Jamming signal')
text(100,-95,'ERP: 20 dBW)text(100,-100,'Jamming bandwidth : 300 MHz')text( 100,-105,'Range to jammer : 50 NM')meta tfig410
56
APPENDIX. B PROBABILITY OF DETECTION VS TARGET RANGE
1. JAMMER ERP : 10 dBW (JAMMING RANGE : 50 NM)
60 80
Range (NM)
57
2. JAMMER ERP : 20 dBW (JAMMING RANGE : 50NM)
0.5
0.4-
0.2
RCS:Case 1
Jammer ERP:20 dBW
Jamming range:50 NM
Sidelabe gain:3.5 dB
BW:Spot:10 MHz
Barrage:300 MHz
<-Mainbe\am Barrage
\<-Sidelobe Spot
20 40
idelobe Barrage
X-No Jamming
60 80
Range (NM)
100 120 40
58
3. JAMMER ERP: 30 dBW (JAMMING RANGE : 50 NM)
60 80
Range (NM)
59
4. JAMMING RANGE 25 NM (JAMMER ERP : 20 dBW)
60 80
Range (NM)
60
5. JAMMING RANGE 100 NM (JAMMER ERP : 20 dBW)
\ \ "ST^Vv 'RCS:Case 1
'
\ \ \ >^ Jammer ERP:20 dBW
0.8
r
1 \ \ n\ Jamming range:100 NM
\ \ \ Sidelobe gain:3.5 dB
\ \ \ BW:Spot:lO MHz
<-Mimbeam Spot \\ Barrage:300 MHz
g 0.5"0
k-MainbeamABarrage \\
\ \<-Sidelotf^Spot
Probability
I \ ^.-Sidelobe Barrage
i \ \ \\<-No Jamming
0.2
iv.\v20 40 60 80 100 120 140
Range (NM)
61
LIST OF REFERENCES
1. Skolnik,M.I., Introduction to Radar Systems, McGraw - Hill Pulishing Company, 1980.
2. Lothes,R.N., Radar Vulnerability to Jamming, Artech House, 1990.
3. Chrzanowski,E.J., Active Radar Electronic Countermeasures, Artech House, 1990.
4. Schleher,D.C, Introduction to Electronic Warfare, Artech House Inc, 1986.
5. Peter R. Dax, Noise Jamming of Long Range Search Radars, Microwaves, September 1975
6. Barton,D.K., Modem Radar System Analysis, Artech House Inc, 1988.
7. Knott,E.F., Radar Cross Section, Artech House Inc, 1986.
8. Van Brunt,L.B., Applied ECM Vol 1, EW Engineering,Inc, 1987.
9. Van Brunt,L.B., Applied ECM Vol 2, EW Engineering,Inc, 1987.
10. System Design Data For The ASR-9 (Final) in Response to Contract Article I ,Item 5b, •
Westinghouse Electric Co, 1984.
1 1. Advances in primary-Radar Technology, The Licoln Laboratory Journal,Volume 2,
Number 3,1989.
12. Jane's airport equipment. 1991-1992,Jane's Information Group.
13. Barton,D.K,Cook,C.E,Paul Hamilton, E&ixoisJiadar Evaluation Handbook, Artech
House, 1991.
14. The international countermeasurees handbook,14th edition, 1989.
62
INITIAL DISTRIBUTION LIST
No.Copies
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Cameron station
Alexandria, VA 22304-6145
2. Library, Code 052 2
Naval Postgraduate School
Monterey, CA 93943 -5002
3. Chairman, Code EW 1
Department of Electrical Warfare
Naval Postgraduate School
Monterey, CA 93943
4. Professor G.S. Gill, Code EC/GL 2
Department of Electrical and Computer Engineering
Naval postgraduate School
Monterey , CA 93943
5. Professor David Jenn, Code EC/JN 1
Department of Electrical and Computer Engineering
Naval Postgraduate School
Monterey, CA 93943
63
6. Air Force Central Library(Air Force Collage)
Sindaebang Dong, Dong Jak Gu, Seoul
156-010, Republic of Korea
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Sang Su Ri, Nam Yil Myon, Chongwon-Gun, Chungbook-Do
363-840, Republic of Korea
8. Chi, Yoon Kyu
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64
Thesis
C42255 Chi /c.l Evaluation of Ta.&a.r
performance degradationdue to standof/ jamming.
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